Cryogenic Mechanical Alloying of Poly(methyl methacrylate) with

and process considerations, as well as environmental concerns.3,4 An intriguing alternative to conventional polymer blending methodologies is high...
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Macromolecules 2000, 33, 2595-2604

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Cryogenic Mechanical Alloying of Poly(methyl methacrylate) with Polyisoprene and Poly(ethylene-alt-propylene) Archie P. Smith,†,‡ Harald Ade,*,§ C. Maurice Balik,‡ Carl C. Koch,‡ Steven D. Smith,| and Richard J. Spontak*,‡,⊥ Departments of Materials Science & Engineering, Physics, and Chemical Engineering, North Carolina State University, Raleigh, North Carolina 27695; and Corporate Research Division, The Procter and Gamble Company, Cincinnati, Ohio 45239 Received August 26, 1999

ABSTRACT: Mechanical alloying is performed at cryogenic temperatures to incorporate polyisoprene (PI) or its hydrogenated analogue poly(ethylene-alt-propylene) (PEP) into poly(methyl methacrylate) (PMMA) as an example of high-energy solid-state blending. Morphological characterization of the blends by X-ray and electron microscopies confirms that the degree of dispersion of the constituent polymers improves with increasing milling time. Such dispersion in the PEP/PMMA blends is, however, ultimately compromised by phase coarsening when the materials are postprocessed above the PMMA glass transition temperature in the melt. Milling-induced PI cross-linking serves to suppress phase coarsening in PI/ PMMA blends, which remain relatively well-dispersed even after postprocessing. These blends are generally less fracture-resistant than the as-received PMMA due mainly to the accompanying reduction in PMMA molecular weight. Their optical transparency is observed to decrease dramatically with increasing PEP or PI concentration until they appear opaque. An overall improvement in blend properties by mechanical alloying is, however, anticipated upon judicious selection of more degradation-resistant polymers.

Introduction An important technological route for overcoming the physical property limitations of homopolymers is to blend two or more homopolymers together in such fashion that yields specific multifunctional properties.1,2 Blending techniques, however, typically rely on processing polymers as solutions or melts, wherein high chain mobility facilitates phase separation between intrinsically incompatible polymers. Although numerous strategies have been developed to improve polymer compatibility and lessen the degree of phase separation, they often involve additional time, expense, material, and process considerations, as well as environmental concerns.3,4 An intriguing alternative to conventional polymer blending methodologies is high-energy solid-state blending. In this case, polymer chain mobility is drastically reduced, and the possibility of phase separation during blending is virtually eliminated. High-energy solid-state blending generally relies on mechanical agitation to mix two or more polymers. The possibility that such agitation may promote mechanical degradation of the constituent polymers has severely limited the commercial viability of solid-state blending. This shortcoming is, however, being surmounted in such emerging polymer processes as solid-state extrusion5-7 and mechanical milling/alloying.8-13 Mechanical alloying refers to the high-energy ball milling of two or more dissimilar materials to produce * To whom correspondence should be addressed. † Present address: Polymers Division, National Institute of Standards & Technology, Building 224, Gaithersburg, MD 20899. ‡ Department of Materials Science & Engineering, North Carolina State University. § Department of Physics, North Carolina State University. | The Procter and Gamble Company. ⊥ Department of Chemical Engineering, North Carolina State University.

powders in which the materials are intimately mixed on the molecular or atomic scale.14 This technique, illustrated in Figure 1, produces nonequilibrium systems and novel materials, such as the oxide-dispersionstrengthened alloys initially developed for the aerospace industry.15,16 With the subsequent discovery that mechanical alloying could yield amorphous metal alloys,17 applications that employ mechanical alloying as a means of mixing inorganic materials have greatly increased and diversified.14,18,19 The utility of mechanical alloying in obtaining unique multifunctional materials from commodity feedstock has not, however, extended to the organic materials arena until quite recently. Efforts designed to mechanically alloy organic materials now include both small organic molecules20-23 and polymers.8-13,24-26 While small improvements in the physical properties of polymer blends produced by mechanical alloying8,11 have been reported, the morphological characteristics of such blends presently remain largely undetermined. An important consideration in the general development of blend morphology and, consequently, blend properties is the nature and degree to which the constituent macromolecules change during processing. Two potential routes for alloying-induced blend modification are schematically depicted in Figure 1. Figure 1a shows that the mechanical action of high-energy ball milling may serve to co-pulverize polymer powder particles, thereby promoting a substantial physical reduction in the scale of dispersion within the system. While this result is nontrivial, the possibility of producing chemically coupled chains in situ (see Figure 1b) could constitute a more important result. The combination of shear, extension, fracture, and cold-welding experienced by polymer powder particles during mechanical alloying is expected to induce chain scission or hydrogen abstraction and, as a result, molecular

10.1021/ma991453v CCC: $19.00 © 2000 American Chemical Society Published on Web 03/17/2000

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Figure 1. Schematic illustration showing the possible effects of solid-state mechanical alloying on polymer blends. In part a, high-energy impact between ball bearings promotes a physical reduction in the size scale of the blended polymers. Another effect is shown in part b, in which free radicals generated by chain scission chemically couple polymer chains and produce a more stable blend.

weight reduction and free radical formation. Reaction of free radicals from broken chains of the same polymer species could affect polymer miscibility and coalescence kinetics, whereas reaction of radicals from different chain species could produce block or graft copolymers as compatibilizing agents under the right set of conditions. To discern the efficacy of cryogenic mechanical alloying in generating novel multiphase polymer systems, we have undertaken a study aimed at incorporating small quantities of polyisoprene (PI) or its hydrogenated analogue poly(ethylene-alt-propylene) (PEP) into the thermoplastic poly(methyl methacrylate) (PMMA). The rigorous requirements established27-30 for a rubber dispersion to yield effective toughening ensure that the present study provides a useful test of the ability of mechanical alloying to produce polymer blends of commercial relevance. Toughening of PMMA is currently performed through the melt addition of multilayer coreshell particles, which are synthesized in a separate emulsion polymerization step.31-33 Since PMMA is produced in high volume due to its excellent optical properties, a simpler method of rubber toughening offers great potential for economic impact. While the chemical similarity between PI and PEP makes these materials attractive candidates for comparison, it must be remembered that PEP is more resistant to radiation-induced degradation and possesses different chain statistics than PI (which could undergo chemical cross-linking at sites of unsaturation). A description of the effects of highenergy mechanical milling on each of the homopolymers employed here is provided elsewhere.34 The present study details the ability of cryogenic mechanical alloying to produce highly dispersed polymer blends (PEP/ PMMA and PI/PMMA) without ex situ compatibilization. Resultant blends are characterized here with respect to phase morphology, impact strength and optical clarity. Experimental Section Poly(methyl methacrylate) (M h n ) 252 000, M h w/M h n ) 4.11) was purchased from Aldrich and used as-received, whereas

Macromolecules, Vol. 33, No. 7, 2000 h w/M h n ) 1.05) was synthesized via living the PI (M h n ) 72 100, M anionic polymerization. A fraction of the PI was subsequently hydrogenated to form PEP. Molecular weight characteristics were determined from gel permeation chromatography. Binary PEP/PMMA and PI/PMMA mixtures were prepared by mechanical alloying performed at cryogenic temperatures so that all components were in the solid (glassy) state. Three grams of polymers in a predesignated mass ratio was placed in a hardened steel vial with 30 g of steel ball bearings (measuring 6.4 and 7.9 mm in diameter). The vial was then sealed under Ar (